Declines in moth populations stress the need for conserving dark nights

Langevelde, Frank van; Braamburg-Annegarn, Marijke; Huigens, Martinus E.; Groendijk, Rob; Poitevin, Olivier; Deijk, Jurriën R. van; Ellis, Willem N.; Grunsven, Roy H. A. van; Vos, R. de; Vos, Rutger; Franzén, Markus; WallisDeVries, Michiel F.

doi:10.1111/gcb.14008

Cited by 98 publications

(82 citation statements)

References 45 publications

(100 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Ecological traps that result in mortality or reproductive failure are predicted to lead to rapid population decline and ultimately extinction (Kokko & Sutherland, ; Robertson, Rehage, & Sih, ). Long‐term records confirm that positively phototactic macro‐moths (Langevelde, Braamburg‐Annegarn, et al, ) in lit habitats (Wilson et al, ) have undergone disproportionate declines in abundance over the past 50 years.…”

Section: Attractionmentioning

confidence: 84%

The impact of artificial light at night on nocturnal insects: A review and synthesis

Owens

Lewis

2018

Ecology and Evolution

256

201

View full text Add to dashboard Cite

In recent decades, advances in lighting technology have precipitated exponential increases in night sky brightness worldwide, raising concerns in the scientific community about the impact of artificial light at night (ALAN) on crepuscular and nocturnal biodiversity. Long‐term records show that insect abundance has declined significantly over this time, with worrying implications for terrestrial ecosystems. The majority of investigations into the vulnerability of nocturnal insects to artificial light have focused on the flight‐to‐light behavior exhibited by select insect families. However, ALAN can affect insects in other ways as well. This review proposes five categories of ALAN impact on nocturnal insects, highlighting past research and identifying key knowledge gaps. We conclude with a summary of relevant literature on bioluminescent fireflies, which emphasizes the unique vulnerability of terrestrial light‐based communication systems to artificial illumination. Comprehensive understanding of the ecological impacts of ALAN on diverse nocturnal insect taxa will enable researchers to seek out methods whereby fireflies, moths, and other essential members of the nocturnal ecosystem can coexist with humans on an increasingly urbanized planet.

show abstract

Section: Attractionmentioning

confidence: 84%

The impact of artificial light at night on nocturnal insects: A review and synthesis

Owens

Lewis

2018

Ecology and Evolution

256

201

View full text Add to dashboard Cite

show abstract

“…Our multi‐scale (seven scales: 50–3,200 m radii) analysis approach allows us to pin‐point the spatial scales at which these homogenization processes are happening. Although we predict homogenization to affect both butterflies and macro‐moths, we predict that homogenization will be more pronounced for the nocturnal macro‐moths than for the diurnal butterflies as ALAN is highly correlated with urbanization (Sutton, ) and as nocturnally active moth species have been shown to display stronger negative population trends than diurnal moth species in the Netherlands, which is affected by ALAN at a country‐wide scale (van Langevelde et al, ). Also, we predict that homogenization will be pronounced at larger spatial scales for macro‐moths than for butterflies.…”

Section: Introductionmentioning

confidence: 81%

“…Since our planet is urbanizing rapidly with associated environmental change that is both profound and predictable (Niemelä, ; Seto et al, ), and since Lepidoptera are bio‐indicators of other flying insect taxa (Merckx et al, ), the strong biotic homogenization that we here observed for Lepidoptera in Belgium is a process that is likely to happen to aerial insect taxa in urbanized settings all over the world. Butterflies and moths occur in basically all terrestrial ecosystems, and given their abundance and diversity they play important functional roles as prey items in food webs, as pollinators in diurnal and nocturnal pollination networks, and as herbivores in nutrient cycling (van Langevelde et al, ; Merckx et al, ). Their severe biotic homogenization as a response to urbanization, and the impacts of urbanization on other flying insect taxa, are hence likely to impact ecosystem function and ecosystem services provision in towns and cities across the globe (Noriega et al, ).…”

Section: Discussionmentioning

confidence: 99%

Urbanization‐driven homogenization is more pronounced and happens at wider spatial scales in nocturnal and mobile flying insects

Merckx

Dyck

2019

Global Ecol Biogeogr

View full text Add to dashboard Cite

Aim We test whether urbanization drives biotic homogenization. We hypothesize that declines in abundance and species diversity of aerial insects are exacerbated by the urbanization‐driven loss of species with low habitat generalism, mobility and warm‐adaptedness. We predict this homogenization to be more pronounced for nocturnal taxa, and at wider scales for mobile taxa. Location Belgium. Time period Summers 2014–2015. Major taxa studied Lepidoptera. Methods We compare communities along urbanization gradients using a shared, replicated and nested sampling design, in which butterflies were counted within 81 grassland and macro‐moths light‐trapped in 12 woodland sites. We quantify taxonomic and functional community composition, the latter via community‐weighted means and variation of species‐specific traits related to specialization, mobility and thermophily. Using linear regression models, variables are analysed in relation to site‐specific urbanization values quantified at seven scales (50–3,200 m radii). At best‐fitting scales, we test for taxonomic homogenization. Results With increasing urbanization, abundance, species richness and Shannon diversity severely declined, with butterfly and macro‐moth declines due to local‐ versus landscape‐scale urbanization (200 vs. 800–3,200 m radii, respectively). While taxonomic homogenization was absent for butterflies, urban macro‐moth communities displayed higher nestedness than non‐urban communities. Overall, communities showed mean shifts towards generalist, mobile and thermophilous species, displaying trait convergence too. These functional trait models consistently fit best with urbanization quantified at local scales (100–200 m radii) for butterfly communities, and at local to wider landscape scales (200–800 m radii) for macro‐moth communities. Main conclusions Urban communities display functional homogenization that follows urbanization at scales linked to taxon‐specific mobility. Light pollution may explain why homogenization was more pronounced for the nocturnal taxon. We discuss that urbanization is likely to impact flying insect communities across the globe, but also that impacts on their ecosystem functions and services could be mitigated via multi‐scale implementation of urban green infrastructure.

show abstract

“…The most influential factors are habitat loss and degradation, pesticides, and climate change (Deutsch et al, 2008;Sánchez-Bayo & Wyckhuys, 2019) although other factors include disease, invasive species, and light pollution (van Langevelde et al, 2018). The most influential factors are habitat loss and degradation, pesticides, and climate change (Deutsch et al, 2008;Sánchez-Bayo & Wyckhuys, 2019) although other factors include disease, invasive species, and light pollution (van Langevelde et al, 2018).…”

Section: Multifarious Causes Of Insect Declinesmentioning

confidence: 99%

Declines in insect abundance and diversity: We know enough to act now

Forister

Pelton

Black

2019

Conservat Sci and Prac

229

172

View full text Add to dashboard Cite

Recent regional reports and trends in biomonitoring suggest that insects are experiencing a multicontinental crisis that is apparent as reductions in abundance, diversity, and biomass. Given the centrality of insects to terrestrial ecosystems and the food chain that supports humans, the importance of addressing these declines cannot be overstated. The scientific community has understandably been focused on establishing the breadth and depth of the phenomenon and on documenting factors causing insect declines. In parallel with ongoing research, it is now time for the development of a policy consensus that will allow for a swift societal response. We point out that this response need not wait for full resolution of the many physiological, behavioral, and demographic aspects of declining insect populations. To these ends, we suggest primary policy goals summarized at scales from nations to farms to homes.

show abstract

Declines in moth populations stress the need for conserving dark nights

Cited by 98 publications

References 45 publications

The impact of artificial light at night on nocturnal insects: A review and synthesis

The impact of artificial light at night on nocturnal insects: A review and synthesis

Urbanization‐driven homogenization is more pronounced and happens at wider spatial scales in nocturnal and mobile flying insects

Declines in insect abundance and diversity: We know enough to act now

Contact Info

Product

Resources

About